稳定同位素稀释气相色谱-三重四极杆质谱法测定水产品中15种卤代多环芳烃

doi:10.3724/SP.J.1123.2022.11001

色谱 ›› 2023, Vol. 41 ›› Issue (6): 527-534.DOI: 10.3724/SP.J.1123.2022.11001

稳定同位素稀释气相色谱-三重四极杆质谱法测定水产品中15种卤代多环芳烃

李鑫玉¹^,², 赵芳¹, 平华¹, 马智宏¹, 李冰茹¹, 马挺军²^,^*(), 李成¹^,^*()

1.北京市农林科学院质量标准与检测技术研究所, 北京 100097
2.北京农学院食品科学与工程学院, 北京 102206

收稿日期:2022-11-02 出版日期:2023-06-08 发布日期:2023-06-01
通讯作者: *Tel:(010)8079917, E-mail:mtingjun@163.com(马挺军);Tel:(010)51503248,E-mail:lic@iqstt.cn(李成).
基金资助:
北京市农林科学院创新能力建设专项(CZZJ202102);北京市农林科学院创新能力建设专项(KJCX20210424);北京市农林科学院创新能力建设专项(KJCX20200302)

Determination of 15 halogenated polycyclic aromatic hydrocarbons in aquatic products by stable isotope dilution coupled with gas chromatography-triple quadrupole mass spectrometry

LI Xinyu¹^,², ZHAO Fang¹, PING Hua¹, MA Zhihong¹, LI Bingru¹, MA Tingjun²^,^*(), LI Cheng¹^,^*()

1. Beijing Institute of Quality Standards and Testing Technology, Beijing Academy of Agriculture and Forestry Sciences, Beijing 100097, China
2. College of Food Science and Engineering, Beijing University of Agriculture, Beijing 102206, China

Received:2022-11-02 Online:2023-06-08 Published:2023-06-01
Supported by:
The Science and Technology Innovation Capacity Building Project of Beijing Academy of Agriculture and Forestry Sciences(CZZJ202102);The Science and Technology Innovation Capacity Building Project of Beijing Academy of Agriculture and Forestry Sciences(KJCX20210424);The Science and Technology Innovation Capacity Building Project of Beijing Academy of Agriculture and Forestry Sciences(KJCX20200302)

摘要/Abstract

摘要：

建立了测定水产品中15种卤代多环芳烃(H-PAHs)的稳定同位素稀释气相色谱-三重四极杆质谱分析方法,分别对仪器条件和前处理方法进行了优化。在提取样品之前加入同位素内标,校准在前处理过程中待测物的损失,再经加速溶剂萃取提取、凝胶渗透色谱柱和PRiME HLB小柱净化后,采用气相色谱-三重四极杆质谱联用仪测定。采用两根DB-5MS色谱柱(30 m×0.25 mm×0.25 μm),利用微板流路控制技术连接两根色谱柱串联使用,可达到较好的分离效果,且目标化合物峰形良好,响应值高。15种H-PAHs在1~50 μg/L内线性关系良好,相关系数(r)≥0.993, H-PAHs相对响应因子(RRF)的相对标准偏差(RSD)值均小于9%,方法检出限为0.009~0.072 μg/kg,方法定量限为0.031~0.240 μg/kg。在空白样品中分别添加0.25、1.0、2.5 μg/kg 3个加标水平的15种H-PAHs混合标准溶液,测定其回收率和精密度,回收率分别为74.6%~116.8%、77.8%~123.2%和71.9%~124.8%, RSD分别为0.6%~8.2%、0.6%~9.0%和0.4%~10.6%。采用所建立的方法对水产品进行检测,实际样品中H-PAHs的总含量为0.60~3.54 μg/kg,其中9-氯菲(9-ClPhe)检出率为100%,且含量最高(1.15 μg/kg)。该方法简化了前处理步骤,具有简便快速、回收率高、稳定性好等优点,适用于实际水产品中H-PAHs的定性、定量分析,为研究H-PAHs在水产品中的残留状况和风险评价提供了可靠的技术支持。

关键词: 同位素稀释法, 气相色谱-三重四极杆质谱, 卤代多环芳烃, 水产品

Abstract:

Halogenated polycyclic aromatic hydrocarbons (H-PAHs), including chlorinated polycyclic aromatic hydrocarbons (Cl-PAHs) and brominated polycyclic aromatic hydrocarbons (Br-PAHs), are compounds in which one or more hydrogen atoms replaced by chlorine or bromine atoms. These compounds are not only difficult to degrade but also highly fat soluble and toxic. They are a new type of high-risk organic pollutants with structures similar to those of dioxins, and their toxicity is even higher than that of the parent polycyclic aromatic hydrocarbons (PAHs). The bioaccumulation of H-PAHs can be predicted by their octanol-water partition coefficient (K_ow); in general, higher bioaccumulation capacity and K_ow values indicate greater fat solubility. Therefore, animal-derived foods with higher fat contents, such as animal meat, milk, aquatic products, and their processed forms, are more likely to be contaminated with higher contents of H-PAHs than those with lower fat contents. In this work, a gas chromatography-triple quadrupole mass spectrometry (GC-MS/MS) method coupled with stable isotope dilution was established to determine 15 H-PAHs in aquatic products. The instrument and pretreatment methods were systematically optimized. The GC-MS/MS used in this method can effectively eliminate matrix interferences and features high sensitivity and low analytical cost; thus, it has good application prospects. The samples were added with an isotope internal standard before extraction to calibrate the loss of the tested substance during the pretreatment process, extracted by accelerated solvent extraction, purified using gel permeation chromatography and PRiME HLB columns, and then analyzed by GC-MS/MS. The use of two DB-5MS chromatographic columns (30 m×0.25 mm×0.25 μm) and microplate fluidics technology to connect chromatographic columns 1 and 2 in series led to better separation effects, good peak shapes, and high target compound responses. The 15 H-PAHs demonstrated good linearities in the range of 1-50 μg/L, with correlation coefficients (r) greater than or equal to 0.993. The relative standard deviation (RSD) values of the relative response factor (RRF) of the H-PAHs were less than 9%, the method detection limit (MDL) was 0.009-0.072 μg/kg, and the method quantification limit (MQL) was 0.031-0.240 μg/kg. Three spiked levels of 0.25, 1.0, 2.5 μg/kg were added to the blank samples to determine the recovery and precision. The recoveries for these spiked levels were 74.6%-116.8%, 77.8%-123.2%, and 71.9%-124.8%, respectively, and the corresponding RSDs were 0.6%-8.2%, 0.6%-9.0%, and 0.4%-10.6%, respectively. The total actual content of H-PAHs in aquatic product samples was 0.60-3.54 μg/kg. Among the H-PAHs investigated, 9-chlorophenanthrene (9-ClPhe) showed the greatest detection rate (100%) and highest content (1.15 μg/kg), indicating that H-PAHs widely exist in aquatic products. Thus, further assessment of the dietary exposure risk of these compounds is necessary. The developed method simplifies the pretreatment step, and has the advantages of simplicity, rapid analysis, high recoveries, and good stability. It is suitable for the qualitative and quantitative analysis of H-PAHs in actual aquatic product samples and provides reliable technical support for the residue status and risk assessment of H-PAHs in aquatic products.

Key words: isotope dilution method, gas chromatography-triple quadrupole mass spectrometry (GC-MS/MS), halogenated polycyclic aromatic hydrocarbons (H-PAHs), aquatic products

中图分类号:

O658

李鑫玉, 赵芳, 平华, 马智宏, 李冰茹, 马挺军, 李成. 稳定同位素稀释气相色谱-三重四极杆质谱法测定水产品中15种卤代多环芳烃[J]. 色谱, 2023, 41(6): 527-534.

LI Xinyu, ZHAO Fang, PING Hua, MA Zhihong, LI Bingru, MA Tingjun, LI Cheng. Determination of 15 halogenated polycyclic aromatic hydrocarbons in aquatic products by stable isotope dilution coupled with gas chromatography-triple quadrupole mass spectrometry[J]. Chinese Journal of Chromatography, 2023, 41(6): 527-534.

图/表 10

参考文献

[1]	Jin R, Liu G R, Jiang X X, et al. Sci Total Environ, 2017, 593: 390
[2]	Ohura T, Amagai T, Makino M. Chemosphere, 2008, 70(11): 2110
[3]	Zhao C X, Li A, Zhang G X, et al. Environ Sci Technol, 2022, 56(17): 12431
[4]	Zhao C X, Li C X, Wang C, et al. Anal Methods, 2022, 14(14): 1430
[5]	Gao Z Q, Yang X, Peng Y. Environ Chem, 2016, 35(2): 287
[6]	Xie J Q, Tao L, Wu Q, et al. J Hazard Mater, 2021, 419(5): 126164
[7]	Ni H G, Guo J Y. J Agric Food Chem, 2013, 61(8): 2013
[8]	Du Y J, Xu X, Liu Q Z, et al. Sci Total Environ, 2022, 815: 152889
[9]	Kawatsu Y, Masih J, Ohura T. Environ Toxicol Chem, 2021, 41(2): 312
[10]	Liu Q Z, Xu X, Wang L, et al. Ecotoxicol Environ Saf, 2019, 181: 241
[11]	Sei K T, Wang Q, Tokumura M, et al. Chemosphere, 2021, 271: 129535
[12]	Wickrama-Arachchige A U K, Guruge K S, Inagaki Y, et al. Food Chem, 2021, 360: 130072
[13]	Jin R, Liu G R, Zheng M H, et al. Environ Sci Technol, 2017, 51(14): 7945
[14]	Ding C, Ni H G, Zeng H. Sci Total Environ, 2013, 443: 857
[15]	Tan J, Lu X B, Fu L, et al. Ecotoxicol Environ Saf, 2019, 186: 109775
[16]	Li W, Wu S M. Food Control, 2022, 136: 108864
[17]	Ma C, Cao R, Sun S, et al. Chinese Journal of Chromatography, 2022, 40(10): 944
[17]	马畅, 曹蓉, 孙帅, 等. 色谱, 2022, 40(10): 944
[18]	Ohura T, Morita M, Makino M, et al. Chem Res Toxicol, 2007, 20(9): 1237
[19]	Rozentale I, Zacs D, Perkons I, et al. Food Chem, 2017, 221: 1291
[20]	Wickrama-Arachchige A U K, Hirabayashi T, Imai Y, et al. Environ Pollut, 2020, 256: 113487
[21]	Ohura T, Sakakibara H, Watanabe I, et al. Environ Pollut, 2015, 196: 331
[22]	Wang J H, Guo C. J Chromatogr A, 2010, 1217 (28): 4732
[23]	Wang L, Jin F, Li M J, et al. Chinese Journal of Analytical Chemistry, 2013, 41(6): 869
[23]	王丽, 金芬, 李敏洁, 等. 分析化学, 2013, 41(6): 869
[24]	Jin R, Liu G R, Zheng M H, et al. J Chromatogr A, 2017, 1509: 114

No.	Compound	Retention time/min	Quantitative ion pair(m/z)	Qualitative ion pair(m/z)	CE/ eV	No.	Compound	Retention time/min	Quantitative ion pair(m/z)	Qualitative ion pair(m/z)	CE/ eV
1	2-BrFle	15.698	243.8>165.0	165.0>115.0	30, 40	12	1,8-Br₂Ant	29.839	336.0>176.0	334.0>176.0	45, 45
2	9-ClPhe	17.595	212.0>176.0	214.0>176.0	40, 40	13	7-ClBaA	35.417	262.0>226.0	264.0>226.0	40, 40
3	2-ClAnt	17.906	212.0>176.0	214.0>176.0	40, 40	14	7-BrBaA	38.419	305.9>226.0	307.9>226.0	35, 35
4	3-BrPhe	20.166	256.0>176.1	256.0>177.1	40, 40	15	7,12-Cl₂BaA	39.873	296.0>226.0	298.0>226.0	35, 35
5	9-BrPhe	20.454	256.0>176.1	256.0>177.1	40, 40	16	¹³C₆-9-ClPhe	17.587	218.0>182.1	220.0>182.1	45, 45
6	9-BrAnt	20.982	256.0>176.1	256.0>177.1	40, 40	17	¹³C₆-2-ClAnt	17.897	218.0>182.1	220.0>182.1	45, 45
7	9,10-Cl₂Ant	23.114	245.9>176.1	247.9>176.1	35, 35	18	D₉-9-BrPhe	20.300	264.9>184.1	264.9>186.1	40, 40
8	9,10-Cl₂Phe	23.513	245.9>176.1	247.9>176.1	35, 35	19	¹³C₆-1-ClPyr	27.389	242.1>206.0	242.1>207.0	50, 50
9	3-ClFlu	25.384	236.1>200.1	236.1>201.1	45, 45	20	¹³C₆-7-ClBaA	35.409	267.9>232.0	269.9>232.0	35, 35
10	1-ClPyr	27.392	236.1>200.1	236.1>201.1	45, 45	21	¹³C₆-7-BrBaA	38.411	311.9>232.0	313.9>232.0	40, 40
11	3-BrFlu	29.058	280.0>201.0	282.0>201.0	30, 30	22	¹³C₆-7,12-Cl₂BaA	39.865	301.9>232.0	303.9>232.0	40, 40

No.	Compound	Retention time/min	Quantitative ion pair(m/z)	Qualitative ion pair(m/z)	CE/ eV	No.	Compound	Retention time/min	Quantitative ion pair(m/z)	Qualitative ion pair(m/z)	CE/ eV
1	2-BrFle	15.698	243.8>165.0	165.0>115.0	30, 40	12	1,8-Br₂Ant	29.839	336.0>176.0	334.0>176.0	45, 45
2	9-ClPhe	17.595	212.0>176.0	214.0>176.0	40, 40	13	7-ClBaA	35.417	262.0>226.0	264.0>226.0	40, 40
3	2-ClAnt	17.906	212.0>176.0	214.0>176.0	40, 40	14	7-BrBaA	38.419	305.9>226.0	307.9>226.0	35, 35
4	3-BrPhe	20.166	256.0>176.1	256.0>177.1	40, 40	15	7,12-Cl₂BaA	39.873	296.0>226.0	298.0>226.0	35, 35
5	9-BrPhe	20.454	256.0>176.1	256.0>177.1	40, 40	16	¹³C₆-9-ClPhe	17.587	218.0>182.1	220.0>182.1	45, 45
6	9-BrAnt	20.982	256.0>176.1	256.0>177.1	40, 40	17	¹³C₆-2-ClAnt	17.897	218.0>182.1	220.0>182.1	45, 45
7	9,10-Cl₂Ant	23.114	245.9>176.1	247.9>176.1	35, 35	18	D₉-9-BrPhe	20.300	264.9>184.1	264.9>186.1	40, 40
8	9,10-Cl₂Phe	23.513	245.9>176.1	247.9>176.1	35, 35	19	¹³C₆-1-ClPyr	27.389	242.1>206.0	242.1>207.0	50, 50
9	3-ClFlu	25.384	236.1>200.1	236.1>201.1	45, 45	20	¹³C₆-7-ClBaA	35.409	267.9>232.0	269.9>232.0	35, 35
10	1-ClPyr	27.392	236.1>200.1	236.1>201.1	45, 45	21	¹³C₆-7-BrBaA	38.411	311.9>232.0	313.9>232.0	40, 40
11	3-BrFlu	29.058	280.0>201.0	282.0>201.0	30, 30	22	¹³C₆-7,12-Cl₂BaA	39.865	301.9>232.0	303.9>232.0	40, 40

No.	Compound	Linear range/ (ng/mL)	r	RSD/ %	MDL/ (μg/kg)	MQL/ (μg/kg)
1	2-BrFle	1-50	0.999	3.9	0.012	0.041
2	9-ClPhe	1-50	0.994	5.6	0.055	0.157
3	2-ClAnt	1-50	0.993	8.7	0.009	0.031
4	3-BrPhe	1-50	0.998	5.0	0.015	0.076
5	9-BrPhe	1-50	0.994	7.4	0.027	0.091
6	9-BrAnt	1-50	0.998	5.4	0.040	0.132
7	9,10-Cl₂Ant	1-50	0.996	4.4	0.015	0.071
8	9,10-Cl₂Phe	1-50	0.997	4.2	0.019	0.054
9	3-ClFlu	1-50	0.997	3.6	0.072	0.240
10	1-ClPyr	1-50	0.999	3.0	0.014	0.075
11	3-BrFlu	1-50	0.999	7.4	0.018	0.092
12	1,8-Br₂Ant	1-50	0.995	5.1	0.019	0.058
13	7-ClBaA	1-50	0.997	8.1	0.032	0.092
14	7-BrBaA	1-50	0.996	4.4	0.053	0.167
15	7,12-Cl₂BaA	1-50	0.998	3.2	0.023	0.112

No.	Compound	Linear range/ (ng/mL)	r	RSD/ %	MDL/ (μg/kg)	MQL/ (μg/kg)
1	2-BrFle	1-50	0.999	3.9	0.012	0.041
2	9-ClPhe	1-50	0.994	5.6	0.055	0.157
3	2-ClAnt	1-50	0.993	8.7	0.009	0.031
4	3-BrPhe	1-50	0.998	5.0	0.015	0.076
5	9-BrPhe	1-50	0.994	7.4	0.027	0.091
6	9-BrAnt	1-50	0.998	5.4	0.040	0.132
7	9,10-Cl₂Ant	1-50	0.996	4.4	0.015	0.071
8	9,10-Cl₂Phe	1-50	0.997	4.2	0.019	0.054
9	3-ClFlu	1-50	0.997	3.6	0.072	0.240
10	1-ClPyr	1-50	0.999	3.0	0.014	0.075
11	3-BrFlu	1-50	0.999	7.4	0.018	0.092
12	1,8-Br₂Ant	1-50	0.995	5.1	0.019	0.058
13	7-ClBaA	1-50	0.997	8.1	0.032	0.092
14	7-BrBaA	1-50	0.996	4.4	0.053	0.167
15	7,12-Cl₂BaA	1-50	0.998	3.2	0.023	0.112

No.	Compound	0.25 μg/kg			1.0 μg/kg			2.5 μg/kg
No.	Compound	Recovery/%	RSD/%	Batch RSD/%	Recovery/%	RSD/%	Batch RSD/%	Recovery/%	RSD/%	Batch RSD/%
1	2-BrFle	75.5	1.6	0.9	110.0	3.8	2.4	99.3	2.4	3.5
2	9-ClPhe	116.8	8.2	1.2	104.7	6.4	3.5	103.1	1.2	4.2
3	2-ClAnt	74.6	2.3	0.7	92.9	5.4	1.2	93.4	10.6	1.7
4	3-BrPhe	85.1	4.0	2.1	121.2	7.3	1.6	124.8	5.2	2.6
5	9-BrPhe	106.5	3.4	0.6	107.8	5.0	1.2	109.6	3.1	3.8
6	9-BrAnt	76.7	2.6	1.3	77.8	2.8	2.4	72.8	8.5	2.1
7	9,10-Cl₂Ant	101.1	4.6	0.7	101.7	1.9	2.7	91.1	4.0	1.5
8	9,10-Cl₂Phe	76.9	1.0	1.4	88.8	5.1	1.9	71.9	2.0	1.9
9	3-ClFlu	103.2	0.8	1.3	123.2	1.7	0.8	113.3	1.7	0.8
10	1-ClPyr	96.7	1.0	1.7	94.8	2.4	1.6	91.9	0.4	0.6
11	3-BrFlu	90.1	2.0	2.4	108.2	1.2	2.8	106.3	2.7	2.7
12	1,8-Br₂Ant	111.9	0.6	1.6	116.8	4.0	3.4	99.6	4.1	3.1
13	7-ClBaA	87.4	3.6	1.8	86.6	3.2	2.4	80.0	2.0	2.1
14	7-BrBaA	82.3	5.2	2.6	88.7	0.6	2.1	82.8	3.2	1.9
15	7,12-Cl₂BaA	75.6	7.2	3.1	78.1	9.0	0.9	73.9	3.1	1.5

稳定同位素稀释气相色谱-三重四极杆质谱法测定水产品中15种卤代多环芳烃

Determination of 15 halogenated polycyclic aromatic hydrocarbons in aquatic products by stable isotope dilution coupled with gas chromatography-triple quadrupole mass spectrometry

RichHTML

PDF

可视化

摘要/Abstract

引用本文

使用本文

扫码分享

图/表 10

参考文献

相关文章 15

编辑推荐

Metrics

No.	Compound	Yellow croaker	Crayfish	Turbot	Crucian	Butterfish	Grass carp	Weever	Crab	Carp		Hairy crab
1	2-BrFle	ND	ND	ND	ND	ND	ND	ND	ND	0.28		ND
2	9-ClPhe	0.82	0.80	0.69	0.75	0.66	0.78	0.77	1.15	0.53		0.60
3	2-ClAnt	ND	ND	ND	ND	ND	ND	ND	ND	ND		ND
4	3-BrPhe	0.26	ND	ND	ND	ND	ND	ND	ND	ND		ND
5	9-BrPhe	ND	ND	ND	ND	ND	ND	ND	ND	ND		ND
6	9-BrAnt	ND	ND	ND	ND	ND	ND	ND	ND	ND		ND
7	9,10-Cl₂Ant	ND	ND	ND	ND	ND	ND	ND	ND	ND		ND
8	9,10-Cl₂Phe	0.38	ND	ND	0.33	ND	ND	ND	ND	ND		ND
9	3-ClFlu	0.55	ND	ND	0.40	ND	ND	ND	ND		ND		ND
10	1-ClPyr	0.43	ND	ND	0.30	ND	ND	ND	ND		ND		ND
11	3-BrFlu	0.41	ND	ND	0.34	ND	ND	ND	ND		ND		ND
12	1,8-Br₂Ant	ND	ND	ND	ND	ND	ND	ND	ND		0.36		ND
13	7-ClBaA	0.25	ND	ND	ND	ND	ND	ND	ND		ND		ND
14	7-BrBaA	ND	ND	ND	ND	ND	ND	ND	ND		0.29		ND
15	7,12-Cl₂BaA	0.44	ND	ND	0.29	ND	ND	ND	ND		ND		ND

[1]	童学智, 陈东洋, 冯家力, 范翔, 张昊, 杨胜园. QuEChERS-超高效液相色谱-串联质谱法快速测定水产品中5种卤代苯醌[J]. 色谱, 2023, 41(6): 490-496.
[2]	刘洪媛, 金静, 郭崔崔, 陈吉平, 胡春. 同位素稀释气相色谱-三重四极杆质谱法测定环境空气中的多氯萘[J]. 色谱, 2022, 40(7): 644-652.
[3]	杨霄, 万译文, 黄华伟, 索纹纹, 肖维, 李小玲. 分散固相萃取-超高效液相色谱-串联质谱法测定水产品中5种硝基咪唑类和6种苯二氮卓类药物[J]. 色谱, 2022, 40(7): 625-633.
[4]	荣杰峰, 许美珠, 张志勇, 邹强, 徐敦明, 钟坚海, 张松艳, 乐有东, 佘紫文. 气相色谱-三重四极杆质谱法测定植物源性食品中棉隆及其代谢物异硫氰酸甲酯残留[J]. 色谱, 2022, 40(7): 661-668.
[5]	石芳, 寿旦, 金米聪, 王宏伟, 陈旭光, 朱岩. 分散固相萃取-高效液相色谱法测定水产品中7种麻醉剂[J]. 色谱, 2022, 40(2): 139-147.
[6]	王兴益, 陈彦龙, 李攻科. 氟化共价有机聚合物固相微萃取-高效液相色谱测定水产品中丁香酚类麻醉剂[J]. 色谱, 2021, 39(9): 1012-1020.
[7]	钱冲, 张梅, 刘珊珊, 勾新磊, 王尉, 胡光辉. 衍生化-气相色谱-三重四极杆质谱法测定泼尼松龙中联氨[J]. 色谱, 2021, 39(7): 750-757.
[8]	詹未, 韩志宇, 李勇, 刘非, 张永. 吹扫捕集-气相色谱-三重四极杆质谱法同时测定饮用出厂水中6种卤乙腈[J]. 色谱, 2021, 39(7): 758-763.
[9]	杨志敏, 张文, 吴福祥, 王行智, 许晓辉. 气相色谱-三重四极杆质谱动态多反应监测模式测定枸杞干果中118种农药残留[J]. 色谱, 2021, 39(6): 659-669.
[10]	张静星, 郑晓燕, 谭丽, 刘进斌, 于海斌. 同位素稀释-高分辨气相色谱/高分辨质谱测定大气中有机氯农药[J]. 色谱, 2021, 39(5): 541-551.
[11]	王兴益, 陈彦龙, 肖小华, 李攻科. 水产品中有害物质分析样品前处理技术研究进展[J]. 色谱, 2021, 39(1): 34-45.
[12]	宿书芳, 孙立臻, 薛霞, 公丕学, 魏莉莉, 李新玲, 祝建华, 刘艳明, 张峰. 通过式固相萃取-超高效液相色谱-串联质谱法测定水产品中地西泮[J]. 色谱, 2020, 38(7): 791-797.
[13]	江丰, 余婷婷, 李珉, 荣茂, 韩莉, 宋哲, 朱晓玲. 加速溶剂萃取同步净化-同位素内标-气相色谱-高分辨质谱测定水产品中32种多氯联苯[J]. 色谱, 2020, 38(7): 853-860.
[14]	孙灵慧, 陈捷, 徐娟, 李敏青, 陈文锐. 衍生化-气相色谱-三重四极杆质谱法同时测定粮食作物中三氯甲基吡啶及其代谢物残留[J]. 色谱, 2020, 38(6): 695-701.
[15]	魏丹, 国明, 张菊. 加速溶剂萃取-磁固相萃取-高效液相色谱-串联质谱法测定水产品中10种氟喹诺酮类药物残留[J]. 色谱, 2020, 38(12): 1413-1422.